NO125336B - - Google Patents

Description

Breaker with arc extinguishing using a stream of pressure medium produced by the ice itself arc.

In the case of electrical switches for high power

and with arc extinguishing by means of a stream of pressure medium produced by itself

the arc, is the pressure development in extinguishing;

the chamber determining a certain-;

effective arc extinguishing. in

The pressure development is first of all dependent on the size of the current to be broken, and secondly dependent on] the heating of the extinguishing agent volume from! the arc, during which the length of the arc has a significant influence on the pressure rise,

The pressure rise and time for this is!

however, of greatest importance for the extinguishing-in process, which should be completed in the course of, at most, 1-2 half-cycles of the current.) In the case of switches with arc extinguishing by means of

of one-pressure gas flow produced by a! foreign source (compressor etc.), this problem does not occur as the extinguishing pressure medium is already available before the contact separation. in

Also for switches with arc extinguishing by means of a stream of pressure medium produced by the arc itself to maintain

satisfactorily betrayed by extinguishing medium

under the required pressure in the extinguishing chamber already before the extinguishing process, becomes

where, according to the invention, an in-, direction so!m is proposed will be described in the following.

With this device, the arc quickly jumps to its full total length, and at the same time a maximum pressure rise is produced, resp. pressure wave. Below this, the arc jumps to its total length within half a half-period of the current, and the corresponding pressure wave, resp. pressure rise produces during this time. To this end, the arc is divided by means of a contact device into several sub-arcs which, thanks to the shape of the counter contacts, unite to form an arc that burns along its entire length. The contact device consists of three or more movable contact pins which connect several spring-loaded fixed contacts. The individual fixed contacts have elevations that protrude between the contact pins. When the contacts are separated, the individual arcs jump onto the pin contacts of the movable contact and then continue to burn as a full-length arc. To favor the transfer, the surface of the insulated carrier can consist of a semiconductor. The contact pins to produce an arc that springs to its total length are in a mechanically fixed and electrically isolated connection with the main contacts, so the operation takes place jointly. The arc, which thanks to the contact device burns to its full length, only burns for a certain time to store the extinguishing pressure medium in the extinguishing chamber, to then be supplied to the extinguishing electrodes located at the outlet openings. From the outlet openings, conductor elements can extend into the arc chamber and serve to divide the entire length of the burning, pressure-developing arc. The contact device with the long burning arc is guided close past the extinguishing electrodes, resp. the conductor elements, and with the help of the contact pins where the long arc burns, the long, burning arc is forced to flash over at the open contact points formed by the extinguishing electrodes and the conductor elements, and then burn on in three small sub-arcs . The arc that burns at the conductor elements in the extinguishing chamber simultaneously serves to increase the pressure rise, while the small arcs that burn in the outlet openings at the extinguishing electrodes are extinguished by the flowing extinguishing pressure medium. To facilitate the extinguishing process, a current-limiting device can be connected in front of the extinguishing electrodes, such as a resistor etc. To control the flow of extinguishing agent, the outlet openings can be closed with a valve.

Fig. 1 shows in longitudinal section an embodiment of a switch according to the invention with extinguishing the arc in a single extinguishing chamber.

In fig. 2 and 3, the principle is shown for an extinguishing chamber where the pressure-developing arc for the extinguishing process is divided into sub-arcs. Fig. 2 shows a longitudinal section along the line n—II in fig. 3 and fig. 3 shows a broken cross-section largely along the line III-in in fig. 2.

In fig. 1, the extinguishing chamber has walls 1 with outlet openings 2 and 3 where hollow contacts 4 and 5 are arranged, where the pressure medium for extinguishing the arc flows out of the extinguishing chamber 1. The contacts 4 and 5 are outside the extinguishing chamber 1 connected to contacts 6 and 7 which form counter contacts for the pin contacts, 8 and 9 respectively, and are in mechanical connection with the connection contacts 10 and 11.

By means of the external contacts 6, 8 and 7, 9, the voltage is removed from the extinguishing chamber after the extinguishing process. At the same time, these contacts can also be used to break the small currents.

The contacts 4 and 5 interact with the movable contact 12 which forms the main contact, and which is permanently mechanically connected to the insulating piece 13. On the insulating piece 13, the arc contacts 14, 15 and 16 are arranged. The surface of the insulating support part 13 can consist of an electric semiconductor material 17 to favor flashover of the arc at the contacts 14, 15 and 16... Against the contacts 14, 15 and 16 there are contact plates 19 and 20 which are under pressure from the springs 18 and have raised arc foot points 21, 22. De-insulated fixed contact plates 19, 20 slide in guides 23 which limit the movement. The described contact device serves to form the arc:..: The movable contact 12 with an

the arrangement for arcing gets its movement from a mechanical drive device 24 with which the external disconnecting contacts 8, 9 are also mechanically connected.

The described device works as follows: During the disconnection movement, the drive member 24 moves the movable contact 12 with the device for arc formation in the direction along the extinguishing chamber 1. Before the movable main contact 12 leaves its counter contacts 4 and 5, the contacts 14 and 15 slide onto the upper part of the hollow contacts, respectively 4 and 5, and the contacts 14, 19, 16, 20 and 15 now participate in the current transfer so that the main contact 12 leaves the unotkontakts 4 and 5 without arc formation.

Due to the pressure from the springs 18, the contact plates 19, 20 follow unchanged current transmission, with this movement up to the stop 23 and then remain stationary so that the contacts 14, 19, 16, 20 and 15 are now separated and four electric arcs are formed .

During the further movement, these four arcs are forced to travel to the elevated arc foot points 21, 22 and then, due to overlap between the pin contacts 14, 16 and 15, to unite into one arc which, due to the contacts' in- burdened distance, burns with a certain large length.

The optionally provided with a semiconductor 17 surface of the insulating carrier 13 facilitates the skip, resp. the projection of the four arcs to contacts 14, 16 and 15 for unification into one long-burning arc. In the case of a suitably selected rapid disengagement movement, this process takes place in the barrel

of half a half-period of the current, and thus remains there, by means of it with

large length of burning arc in the extinguishing chamber, produced an extremely fast and

strong pressure rise that occurs before the extinguishing process begins.

During the further movement, the arc that burns between the contacts 14, 16 and 15 enters in front of the outlet openings 2 and 3

and jumps over to contacts 4 and 5, where it then still burns for a certain time before finally during the further movement only burning between contacts 4 and 5..

The arc that burns between contacts 4 and 5 is located with its base points in the extinguishing medium that flows out through the outlet openings 2 and 3, and the arc is extinguished with the help of two very strong flows of extinguishing pressure medium produced by the long-burning electric arc.

After the extinguishing process, the voltage between contacts 4 and 5 is removed using contacts 8 and 9.

In the embodiment of fig. 2 and 3, fixed contacts 31 and 32 with connection bolts 33 and 34 are arranged in the extinguishing chamber 30, which are electrically connected to the hollow joints 35 and 36 respectively. The switch knife 37 with the fixed contacts 31 and 32 form the main contacts for current transmission. The switch knife 37 is fixed in an insulating carrier part 38, and on this there are arranged pin contacts 39, 40 and 41, designed to serve as arc foot points. The surface of the insulating support part 38 can also be designed as halves 42 to favor flashover of the electric arc between the contacts 39, 40 and 41, just as auxiliary electrodes 58 and 59 can also be arranged there.

The contacts 39, 40 and 41 have side extensions 43, 44 and 45. The contact device on the insulating support part 38 has as counter contacts the contact plates 46 and 47, sdm is fixed on the insulating plate 48 and is under the pressure of the springs 49.

The contact plates are made wavy, and the elevations 50 and 51 serve to guide the arc foot points. The movement of the contact plate device is limited by stop 52.

In the extinguishing chamber 30, the extinguishing electrodes 53 and 54 are arranged in front of the hollow contacts 35 and 36, respectively, where they serve as outflow openings for the extinguishing pressure medium stored in the extinguishing chamber. The contacts 53 and 54 are formed by the outer ends of two conductor elements which are extended into the extinguishing chamber to form electrodes 55 and 56.

By means of this contact device in front of the outlet openings, the arc gaps 35, 53 — 55, 56 and — 54, 36 are obtained.

In fig. 2, the end position of the movable contact device at the end of the disconnection movement is drawn in dashed lines.

The movement of the contact device is effected by means of the drive member 57.

The device works as follows:

When the switch is opened, the described contact device is set in motion by means of the drive member 57, and the main contacts formed by the switch knife 37 with counter contacts 31, 32 are opened.

Before the contact separation at the main contacts, the pin contacts 39, 40 are slid onto the extended parts of the hollow contacts 35, 36, while the pressure contact plates 46, 47 follow due to the spring pressure, so that the current can take its way over the shunt contacts 39, 46, 41, 47 and 40 in parallel with the main contacts.

The main contacts open without arcing, and the shunt contacts follow this movement. With the help of the stops 52, the contacts 46, 47 are restrained from further movement, and arc formation begins.

Arcs will now burn between contacts 39, 46 — 46, 41 — 41, 47 and 47, 40. These four arcs are then, during the further movement of the overall contact device, brought together by means of the wave-shaped elevations 50, 51 and thus forced to switch over to the contacts 39, 41 and 40.

From now on, an arc burns between these contacts, the length of which is determined by the distance between the contacts.

Thanks to the fast drive movement, this process takes place within half a half-period of the current. The arc has thus quickly sprung to its predetermined maximum length after opening the contacts.

This arc, which burns with its greatest possible length in the extinguishing chamber 30, causes a very rapid and strong rise in pressure, resp. pressure wave in the extinguishing chamber 30. During the further movement, this long burning arc is supplied to the extinguishing electrodes and conductor elements 53, 55, 56 and 54 at the outlet locations.

As can be seen from fig. 3, the lateral extensions 43, 44 and 45 approach the open breaking points 35, 53 /— 55, 56 — 36, 54 which are formed by the extinguishing electrodes and the conductor elements, whereby the arc will switch over to these electrodes so that the long arc at the arc contacts 39, 41 and 40 will go out and be divided into three sub-arcs by means of the conductor elements.

While the arc that burns at the conductor elements 55 and 56 in the extinguishing chamber 30 serves to further maintain the pressure rise, the arcs that burn with a constant short length at the electrodes 35, 53 and 36, 54 form the extinguishing arcs, which are exposed to the flowing extinguishing pressure medium in an efficient manner.

The movable contact device is pulled away from the extinguishing electrodes and conductor elements and no longer participates in the extinguishing process.

The extinguishing pressure medium produced by the long-burning arc, which also receives an addition due to the arc burning at the conductor elements, exerts an effective blowing effect on the arcs burning in the outlet openings, so that these arcs are extinguished.

Thanks to the generation of the long-burning arc and the associated rapid pressure rise, it is possible

with certainty to extinguish the arc within 1 to at most 2 half-cycles of the current,

and the overall extinguishing process is then included.

For better utilization and management of

extinguishing medium, the outlet openings can be supplied with valves which regulate it

flowing extinguishing medium. In connection with the drive movement, you can also

close and open the outlet openings mechanically

in order to release the openings only when the arc burns at the extinguishing point.

It can be used as an extinguishing medium

air, gas in any form, hard gas or a

liquid.

To cause the rapid pressure rise

using the long-burning arc

one can implement the device |with an arbitrarily suitable number of contact pins

and fixed counter contacts.

Claims (8)

1. Electric switch with arc cut-! by means of an extinguishing current produced by the arc itself in an extinguishing chamber, characterized in that a main contact point during the first part of the opening motion is shunted by a series connection of contact points consisting of springy fixed contacts and movable contact pins which, during the further open-; ning movement, draws a plurality of series-connected, short arcs, the foot points of which due to the shape of the fixed contacts are quickly moved so that, due to rapid pressure development in the extinguishing agent, only a long arc occurs, and that this arc eventually remains divided, is transferred to electrodes with outlet openings, where the arc or arcs are extinguished by the flowing extinguishing agent. 2. Switch as specified in claim 1, characterized in that there are three or more movable contact pins (14, 15, 16; 39, 40, 41), and that the fixed contacts (19, 20; 46, 47) are spring-loaded and has elevationsj (21, 22; 50, 51) projecting between the contact pins. 3. Switch as stated in claim 1 or 2, characterized in that the movable contact pins (14, 15, 16; 39, 40, 41) are attached to an insulating support part (13; 38) whose surface consists of an electric semiconductor (17) ; 42) which favors the flashover of the arc burning between the contact pins. 4. Switch as stated in claims 1-3, characterized in that the contact pins (14, 15, 16; 39, 40, 41) are mechanically fixed and electrically isolated connected to the contact by means of the carrier part (13; 38) 12; 37) for the normal current flow (the main contact), so that these two types of contacts move together. 5. Switch as stated in one of the claims 1-4, characterized in that for the aforementioned division of the arc in the extinguishing chamber two conductor elements (55, 56) are arranged which lie one after the other in the longitudinal direction of the arc and partially extend into the outlet openings, and whose ends serve as electrodes for the split arc. 6. Switch as stated in claim 5, characterized in that the contact pins (39, 40, 41) with the long-burning arc are led close past the extinguishing electrodes (35, 53—36, 54) resp. the conductor elements (55, 56) so that the long-burning arc is brought to overlap between the extinguishing electrodes (35, 53—36, 54) and the conductor elements (55, 56) and then continues to burn in three small partial arcs. 7. Switch as stated in claim 6, characterized in that the arc that burns between the conductor elements (55, 56) in the extinguishing chamber serves for additional pressure increase, while the small arcs that burn in the discharge opening are extinguished by means of the outgoing extinguishing pressure medium. 8. Switch as stated in one of claims 1-7, characterized in that the outlet opening is closed with a valve to control the pressure in the extinguishing part.